株式会社グローバルインフォメーション
TEL: 044-952-0102
表紙
市場調査レポート

スモールセルネットワーキングとモバイルバックホール - 市場、技術、応用

Small Cells Networking and Mobile Backhaul - Markets, Technologies and Applications

発行 Practel, Inc. 商品コード 465233
出版日 ページ情報 英文 163 Pages
納期: 即日から翌営業日
価格
本日の銀行送金レート: 1USD=112.34円で換算しております。
Back to Top
スモールセルネットワーキングとモバイルバックホール - 市場、技術、応用 Small Cells Networking and Mobile Backhaul - Markets, Technologies and Applications
出版日: 2017年03月10日 ページ情報: 英文 163 Pages
概要

当レポートでは、スモールセルバックホールソリューションについて取り上げ、スモールセルバックホールの仕様、マクロセルバックホールとの違い、標準化の必要性、産業動向、ベンダーとのインタビュー、統計データの分析など、体系的な情報を提供しています。

第1章 イントロダクション

第2章 段階

  • 4G仕様
  • 5G仕様
  • プロセス

第3章 スモールセルの発展

  • 合理的
  • 用語体系
  • 背景
  • 応用
  • 利点と問題点
  • スモールセル市場
  • 標準化
  • スモールセル産業
    • AirHop Communications
    • Alpha Networks
    • Argela
    • Broadcom
    • BTI Wireless
    • Cavium
    • Cisco
    • CommScope
    • Contela
    • Ericsson
    • 富士通
    • Huawei
    • ip.access
    • Intel
    • Gilat
    • Juni
    • 日本電気
    • Nokia
    • Qualcomm
    • Radisys
    • Samsung
    • Spider Cloud
    • Tektelic
    • TI
    • Xilinx
    • ZTE

第4章 スモールセルバックホール

  • 概要
  • 仕様
  • パラメーター
  • 標準化の必要性
  • 市場の特徴
  • スモールセルバックホール産業
    • Actelis (有線)
    • Airspan (無線バックホールと統合 - 802.11ac - NLOS)
    • Bluwan (42 GHz)
    • BLiNQ (6 GHz 以下)
    • Cambium (6 GHz 以下)
    • Cambridge Broadband (マイクロ波バックホール)
    • CCS (28 GHz 以上)
    • Ceragon (6 GHz 以下、その他)
    • DragonWave (マイクロ波)
    • Exalt (マイクロ波)
    • Intracom (マイクロ波)
    • Genesis (有線)
    • MAX4G (マイクロ波)
    • Polewall (FSO)
    • Radwin (6 GHz 以下)
    • Tarana (LoS、NLoS 3 GHz)
    • Trango System
    • TI (NLoS)
  • サマリー

第5章 結論

目次

Practel is following the small cells technologies development from the beginning of their commercialization and contributed several reports on this subject.

This particular report updates previous studies and adds some new information. The report presents in details and in easily understandable terms independent, unbiased analysis, which reflects progress in small cells and their backhauls solutions. Through vendors' interviews and the analysis of other multiple data sources, the report provides latest, accurate marketing and technological assessment.

In particular, the report provides the analysis of small cells technologies, concentrating on their advantages, issues, varieties and specifics. Major applications are analyzed and standards developments are emphasized. Based on the in-depth industry analysis, which included the analysis of multiple studies and interviews with vendors, market prognoses (2017-2021) are presented. The survey of more than thirty-five vendors and their portfolios is also provided. It is shown that the 4G era (and later, 5G era) will concentrates on building HetNets in which small cells play an important role.

The report stresses that the small cells backhaul solution may prove or brake the small cell business case. Specifics of small cells backhauls, their varieties and differences from macro cells backhauls are analyzed in details. The need for standardization is emphasized. The study of industry trends, interviews with vendors and the analysis of publically available statistical data helped to perform the marketing analysis. The survey of vendors (about 30 manufacturers of small cells backhaul equipment) reflects this industry specifics. There is a range of use cases for open access small cells, from targeted demand hotspots in city centers, through generalized capacity uplift, to serving not-spots in remote rural areas. In each case the emphasis on backhaul requirements shifts, and aspects that are critical to one type of deployment can be relaxed in others. Solutions with different characteristics will address the needs of different types of small cells backhaul in different areas.

Attachments contain the in-depth analysis of promising small cells backhaul microwave solutions:

  • 1. 60 GHz technologies (V-band). Both Ethernet radio and 802.11ad solutions are addressed. Marketing and technical specifics are described in details. The survey of vendors is also provided. The scope of 802.11ay standard- to- be published is also outlined.
  • 2. 802.11ac. The technology allows gigabits throughput, range and other characteristics that satisfy small cell backhaul requirements. Authors analyzed specifics of 802.11ac as they relate to small cell backhaul application; they also analyzed the market and vendors' portfolios.
  • 3. E-band radio. Popularity of this radio for discussed applications is growing; and this trend will be even more pronounced when we are approaching the 5G era.
  • 4. Attachment also reflects the survey of small cell and their backhaul - related patents (2015-2017).

Microwave backhauls for SCs are prevailing now and it is expected that they will keep this leadership position in future.

The report is written for a wide audience of telecommunications specialists that deal with complicated choices in mobile networking to support business cases.

Table of Contents

1.0 Introduction

  • 1.1 General
  • 1.2 Current Situation and Role of Small Cells
  • 1.3 SC Backhaul
  • 1.4 Scope
  • 1.5 Report Structure
  • 1.6 Research Methodology
  • 1.7 Target Audience

2.0 Stages

  • 2.1 4G Specifics
    • 2.1.1 Traffic Volumes and SC
    • 2.1.2 From 3G to 4G
    • 2.1.3 4G Distinguished Features
    • 2.1.3.1 HetNet
  • 2.2 5G Specifics
    • 2.2.1 5G Timetable (3GPP-ITU) and SCs
    • 2.2.2 5G Advances
  • 2.3 Process

3.0 Small Cells Development

  • 3.1 Rational
  • 3.2 Nomenclature
    • 3.2.1 Group
  • 3.3 Background
  • 3.4 Applications
    • 3.4.1 Indoor Use Cases
    • 3.4.2 Outdoor Use Cases
    • 3.4.3 Public Safety Communications
    • 3.4.4 Summary
  • 3.5 Benefits and Issues
  • 3.6 Small Cell Market
    • 3.6.1 Market Geography
    • 3.6.2 Estimate
  • 3.7 Standardization
    • 3.7.1 Organizations
    • 3.7.2 Interfaces - 3GPP
    • 3.7.3 First Standard
    • 3.7.4 3GPP Rel.12 and SCs
  • 3.8 Small Cell Industry
    • Airspan
    • AirHop Communications
    • Alpha Networks
    • Argela
    • Broadcom (acquired by Avago in 2015)
    • BTI Wireless
    • Cavium
    • Cisco
    • CommScope
    • Contela
    • Ericsson
    • Fujitsu
    • Huawei
    • ip.access
    • Intel
    • Gilat
    • Juni
    • NEC
    • Nokia
    • Qualcomm
    • Radisys
    • Samsung
    • Spider Cloud
    • Tektelic
    • TI
    • Xilinx
    • ZTE

4.0 Small Cell Backhaul

  • 4.1 General
    • 4.1.1 Classifications
  • 4.2 Specifics
    • 4.2.1 Change
    • 4.2.2 Differences
  • 4.3 Parameters
    • 4.3.1 Factors
    • 4.3.2 Planning
  • 4.4 Need for Standardization
  • 4.5 Market Characteristics
    • 4.5.1 Components
    • 4.5.2 TCO Factor
  • 4.6 Small Cell Backhaul Industry
    • Actelis (wireline)
    • Airspan (integrated wireless backhaul - 802.11ac - NLOS)
    • Bluwan (42 GHz)
    • BLiNQ (sub - 6 GHz)
    • Cambium (sub-6 GHz)
    • Cambridge Broadband (Microwave Backhaul)
    • CCS (28 GHz and up)
    • Ceragon (sub-6 GHz and other)
    • DragonWave (microwave)
    • Exalt (Microwave)
    • Intracom (Microwave)
    • Genesis (wireline)
    • MAX4G (Microwave)
    • Polewall (FSO)
    • Radwin (sub-6 GHz)
    • Tarana (LoS, NLoS 3 GHz)
    • Trango System
    • TI (NLoS)
  • 4.7 Summary

5.0 Conclusions

  • Attachment A: 60 GHz Radio - SC Backhaul
  • A.1 General
  • A.2 60 GHz Radio - Point-to-Point
    • A.2.1 Spectrum Specifics
    • A.2.2 Oxygen Absorption
    • A.2.3 Antenna Focus
    • A.2.4 Combined Effects
    • A.2.5 Availability
    • A.2.6 Progress in Chip Technology for mmWave Spectrum
      • A.2.6.1 Modulation and Duplexing
      • A.1.6.2 Antenna
      • A.1.6.2.1 Indoor Behavior
      • A.1.6.2.2 Outdoor Behavior - FCC Modifications
    • A.2.7 Summary
    • A.2.8 60 GHz Radio Developments and Market
      • A.2.8.1 Synopsis
      • A.2.8.2 Market Estimate
        • A.2.8.2.1 General
        • A.2.8.2.2 Drivers
        • A.2.8.2.3 Forecast
    • A.2.9 60 GHz Radio - SC Backhaul Choice
    • A.2.10 Industry
      • BridgeWave
      • Fastback
      • SIAE MICROELETTRONICA
      • Ceragon
      • DragonWave
      • Intracom
      • Infineon
      • Lightpointe
      • NEC
      • Plasma Antennas
      • Siklu
      • Solectek
  • A.3 60 GHz Wi-Fi - 802.11ad
    • A.3.1 Advanced Wi-Fi: Benefits and Issues
    • A.3.2 WiGig Alliance
      • A.3.2.1 Union
    • A.3.3 IEEE 802.11ad - 60 GHz Wi-Fi
      • A.3.3.1 Status
      • A.3.3.2 Coexistence
      • A.3.3.3 Scope
        • A.3.3.3.1 Channelization
        • A.3.3.3.2 PHY
        • A.3.3.3.3 MAC
        • A.3.3.3.4 Specifics
        • A.3.3.3.5 Summary
        • A.3.3.3.6 802.11ad and SC Backhaul
      • A.3.3.4 Industry
        • Analog Devices
        • Collaboration
        • Intel
        • InterDigital-BlueWireless
        • Lattice
        • Nitero
        • Peraso
        • Tensorcom
        • Qualcomm Atheros
        • Additional Information
      • A.3.3.5 Certification
      • A.3.3.6 Market
        • A.3.3.6.1 Market Drivers
        • A.3.3.6.2 Usage Models
        • A.3.3.6.3 Estimate
  • A.4 802.11ay
  • Attachment B: 802.11ac
  • B.1 Approval
  • B.2 General - Improving 802.11n Characteristics
  • B.3 Major Features
  • B.4 Major Benefits
    • B4.1 Waves
  • B.5 Usage Models
  • B.6 Projections
  • B.7 Industry
    • Ackrion
    • Airspan Networks
    • Mimosa
  • Attachment C: E-band Radio - SC Backhaul Solution
  • C.1 Benefits
    • C1.1 Typical Characteristics
  • C.2 Market
  • C.3 Vendors
    • Aviat
    • DragonWave
    • E-band Communications
    • Fujitsu
    • Intracom
    • Infineon
    • LightPointe
    • Loea
    • NEC
    • Siklu
  • Figure 1: Mobile Data Traffic Growth - Global (Petabytes/Month)
  • Figure 2: ITU-R Schedule for IMT-2020 Development
  • Figure 3: 3GPP - Tentative Timeline - 5G Standardization
  • Figure 4: Major Network Characteristics - 5G
  • Figure 5: mmWave Advantages
  • Figure 6: Macro vs Small BS - Shipped (Ratio)
  • Figure 7: BS: Characteristics and Classification
  • Figure 8: SC Parameters
  • Figure 9: Use Cases
  • Figure 10: Summary: Small Cells Backhauling Choices: Benefits and Issues
  • Figure 11: Estimate: SC Global Shipments (Mil. Units)
  • Figure 12: Estimate: Global SC Shipments ($B)
  • Figure 13: 3GPP Rel. 12 SC Enhancements
  • Figure 14: Scenario 1
  • Figure 15: Scenario 2
  • Figure 16: SC Backhaul Illustration
  • Figure 17: SC Backhaul Types
  • Figure 18: (a) Non-ideal; and (b) Ideal SC Backhaul Characteristics
  • Figure 19: Technological Changes
  • Figure 20: Summary: Specifics of SC Backhauls vs Macrocells
  • Figure 21: Estimate: SC Backhaul - Global Market ($B)
  • Figure 22: Estimate: Global Market - SC Microwave Backhaul ($B)
  • Figure 23: PMP and PTP Architectures
  • Figure 24: 60 GHz Radio Use Cases
  • Figure 25: Attenuation in 60 GHz Band
  • Figure 26: Signal Absorption
  • Figure 27: Directivity
  • Figure 28: Bands Features Comparison - Illustration
  • Figure 29: 60 GHz Links Characteristics
  • Figure 30: 60 GHz Link Characteristics
  • Figure 31: Global Market - SC Backhaul - 60 GHz Radio ($B)
  • Figure 32: 60 GHz SC Backhaul Characteristics
  • Figure 33: Licensed and Unlicensed Bands Transmission
  • Figure 34: 802.11ad Major Features
  • Figure 35: 802.11ad PHY - Modulation
  • Figure 36: 802.11ad MAC
  • Figure 37: Summary
  • Figure 38: 60 GHz Wi-Fi Usage Models
  • Figure 39: Estimate: Tri-band Wi-Fi Chipsets Sales - Global (Bil. Units)
  • Figure 40: Estimate: Global Sales Tri-band Wi-Fi Chipsets ($B)
  • Figure 41: Estimate: Global Sales-802.11ad Chipsets (Bil. Units)
  • Figure 42: Estimate: Global Sales-802.11ad Chipsets ($B)
  • Figure 43: Functionalities
  • Figure 44: Channel Assignment: 802.11ac
  • Figure 45: Rates: 802.11ac
  • Figure 46: Channel Size/Rate
  • Figure 47: Wave I and Wave II
  • Figure 48: Usage Models
  • Figure 49: 802.11ac Consumers AP Shipping (Mil. Units)
  • Figure 50: Illustration - E-band Radio - Backhauling Mobile Network
  • Figure 51: Regulations
  • Figure 52: E-Band Radio Generations
  • Figure 53: Estimate: Global Market-SC Backhaul-E-band Radio ($B)
Back to Top